Shoe machine



O. R. HAAS SHOE MACHINE` May 11, 1937.

Original Filed March 19, 1932 11 Sheets-Sheet 1 O. R. HAAS SHOE MACHINE May l1, 1937.

11 Sheets-Sheet 2 l original Filed March 19, 1932 Winess www O. R. HAAS SHOE MACHINE May 11, 1937.

Original Filed March 19, 1932 ll Sheets-Sheet 3 ww, /W

Wzlness O. R. HAAS SHOE MACHINE May 11, 1937.

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SHOE MACHINE Original Filed March 19, 1952 l1 Sheets-Sheet 5 Fig. 5

lnvenar Witness @Mm O. R. HAAS SHOE MACHINE vMay 11, 1937.

Original Filed March 19, 1932 l1 Sheets-Sheet 6 W73 V2/ess May11,1937. QRHAAS 2,080,076

SHOE MACHINE Original Filed March 19, 1952 ll Sheets-Sheet 7 Fig. 7

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May 11, 1937. Q R, HAAS 2,080,076

SHOE MACHINE Original Filed March 19, 1932 ll Sheets-SheetB Witness 6 oo Z Maly 11, 1,937. R HAAS v 2,080,076

. sHoE MACHINE Original Filed March 19, V1932 11 Sheets-Sheet 9 L Iwenr Wness @www/M O. R. HAAS SHOE MACHINE May Il., 1793-7.y

1l Sheets-Sheet 10 Original Filed March 19, 1932 May 11, 1937. Q, R, HAAS 2,080,076

SHOE MACHINE Original Filed March 19, 1932 11 Sheets-Sheet 11 "lll/lll I d? f. l

Patented May 11, i937 UNHTED STA? SHOE MACHINE Original application March 19, 1932, Serial No.

' 600,016. Divided and 1935, Serial No. 19,211

26 Claims.

The present invention relates to shoe machines and is herein set forth as embodied in an outsole stitcher of the type in which the shoe and the stitch forming devices are moved relatively to 5 transfer the point of operation about the shoe and to change the relative positions of the shoe and the operating means to present the shoe properly to the operating means as the point of operation is transferred about the shoe, and in l() which the shoe is supported in operating position in the machine, and all of its movements are effected and controlled by automatically acting mechanisms. A machine of this type is disclosed in applicants prior Patent No. 2,031,479, granted February 18, 1936 on an application Serial No. 600,016, for Shoe sewing machines, led March 19, 1932, of which the present application is a division.

The primary object of the present invention is to improve the construction and mode of operation of automatic outsole shoe sewing machines and to produce a machine of this type which is more efficient, reliable and uniform in its operation than prior machines and upon which an operation on a shoe may be successfully performed by a comparatively unskilled operator with a minimum expenditure of labor and time. Certain features of the invention may be utilized to advantage in connection with shoe sewing machines other than outsole stitchers, or in connection with machines for performing other shoe making operations. Also, certain features are not limited to use in machines which are wholly automatic in character, but may be em- 35 bodied in machines in which, at least some of the required relative movements of the operating instrumentalities and shoe are produced or controlled by the operator.

In operating prior automatic shoe machines,

40 considerable manual effort has been required to set the machine in operation due to the frictional resistance of the starting mechanism, to the necessary mass of the manipulated parts and to the number of different operations performed simultaneously or in timed relation to the coupling of the rotating parts to the power driver.

An important feature of the present invention, therefore, contemplates the provision of a manually controlled power driven starting apparatus for coupling a shoe machine to a power driving member to relieve the operator of the physical exertion which would otherwise be required and to insure uniform and certain actuation of the coupling parts in suitable timed relation to any secondary operations that may be required or this application May 1,

considered desirable. In the machine hereinafter described this feature of the invention is embodied in a construction comprising a power driving member, a main driven member, a main clutch for coupling the driving member to the driven member, an auxiliary shaft, an auxiliary clutch for coupling the auxiliary shaft to actuate the main clutch, and a manual control for causing the engagement of the auxiliary clutch. In the construction hereinafter described, this auxiliary shaft, in addition to causing the actuation of the main clutch is also utilized for performing certain preliminary operations to place the various parts of the machine in proper position to act on the shoe when the machine is started. The machine in which the several features of the present invention have been embodied is an automatic outsole stitcher and, in this machine, 'the preliminary operations performed by the auxiliary shaft during or prior to the throwing in of the main clutch consist in locking a portion of the jack actuating mechanism, which has been adjusted in accordance with the size of the shoe by the movement of the shoe into the machine and in adjusting a portion of the driving mechanism for operation on the size of shoe which is in the jack.r

The automatic machine hereinafter described is of that type which comprises a jack upon which the shoe tc be operated upon is supported` and to which positioning movements are imparted to cause the shoe to be presented properly to the operating means as the point of operation is transferred about the shoe. In machines of this type, the jack is rotatably mounted upon a jack supporting structure consisting of a plurality of members pivotally connected to swing about a plurality of axes. A feature of the present invention relates to an improved jack supporting structure and means for imparting the required positioning movements to the jack and more particularly to an improved construction and arrangement of parts for producing and controlling the rotating movements of the jack. In prior construction the rotary movements of the jack have been produced and controlled by means of a cable leading from a power actuated drum, mounted in the frame of the machine, over guiding pulleys on the jack supporting structure to a pulley at the lower end of the jack. In order to improve and simplify this jack rotating mechanism and to enable the jack to be rotated and its rotative position controlled in a uniform and accurate manner, regardless of any jack positioning movements which may be imparted to the swinging members of the jack supporting structure, this feature of the invention contemplates providing guides for the cable so that on its way from the power actuated drum on the frame of the machine to the pulley on the jack, it passes through the axes about which the pivoted members of the support swing. By arranging the guides so that the cable passes through the axes about which the pivoted members of the jack support swing, the length of cable between the pulley at the lower end of the jack and the power actuated drum on the frame of the machine remains constant., being unaffected by any swinging movements which may be imparted to the `iack support in any direction, and thus the rotative movements of the jack and its rotative position can be accurately and uniformly produced and controlled to maintain the edge of the shoe sole at the sewing point always parallel to the line of feed, and the production of an outseam properly located on the shoe and stitches of uniform length can be insured.

In an automatic shoe machine in which the feeding devices operate. directly on the shoe, it is necessary or desirable to provide means whereby the shoe may be kept in time with the position changing mechanism which operates to cause the shoe to be presented properly to the operating devices as the. point of operation is transferredalong the` shoe. Afeature of the present invention is embodied in an improved mechanism for securingthis result and, as hereinafter described, comprises a change speed gearing in the connections for driving the pattern cam shaft from which positioning movements are imparted to the jack.

The features of invention above referred to and other novel constructions, combinations and arrangements of parts hereinafter described and claimed will be readily understood by those skilled in the art from the following. description taken in connection with the accompanying drawings which illustrate an automatic outsole stitcher constituting one specific embodiment of the several features of the invention.

In the drawings Figure 1 is a view in front elevation of a complete automatic outsole stitcher embodying the several features of the invention with the lower portion of the main base, the motor, and certain other parts broken off; Figure 2 is a plan view of the machine with the frames for the power drive and sewing mechanism removed, and with the base partly broken awa),7 to show the construction and mechanism within thebase; Figure 3 is a sectional plan view of the machine on a plane passing just below the top of the base, parts having been. removed to simplify illustration; Figure 4 is a plan View, partially in section on an enlarged scale showing the mechanism below the motor and parts of the sewing mechanisms; Figure 5 is a view in elevation of the upper portion. of the machinev from the right side, partly in section, illustrating particularly the driving and stopping mechanism; Figure 6-is a view in front elevation, partly in section of an upper'portion of the machine; Figure 7 is a view similar to. Figure 5, parts having been broken away and shown in section along a plane passing. through the machine nearer to the right side; Figures 8 and 9 are sectional views in side elevation of a portion of the jack supporting andv actuatingmechanisms in different positions on the same scale as Figure 2; Figure 10 is a side sectional view taken along the line ill-lil of y Figure 2; Figure 1l illustrates diagrammatically a wiring system for electrically connecting Various parts of the machine; Figure l2 is a detail plan View of a lost motion switch; Figure 13 is a sectional View in front elevation of the switch indicated in Figure 12; Figure i4 is a detail view showing, in side elevation and section, certain of the parts connected with the driving and stopping mechanism; and Figure 15 is a detail sectional view taken along the line li- I5 of Figure lll.

Referring to Figures l and 2 of the drawings, the frame of the machine comprises a main base 2 havinga horizontal top 4. Suspended through an opening in the top is a cradle 6, machined to carry the frames 8 and l0 for the power drive and thesewing mechanism, respectively. The power drive frame 8 supports a casting I2 carrying the power starting mechanism, and a driving motor Hi is attached to a flange at the top of the power starting casting.

The motor it is mounted to drive a vertical shaft IS (see Figs. 4.-, 5, and 7), for operating the constantly rotating main power driver, indicated at i8. The upper end of shaft i 6 is supported within the motor and the lower end, by a bearing 2Q carried by a sleeve 22 formed in the power starting casting i2. The connection between the motor shaft i6 and the power driver i8 comprises a spur gear 24 fixed to the motor shaft i5 which meshes with and drives an idler gear 26 rotating on a fixed shaft and meshing with an internal gear 28 formed on the power driver i8. The power driver is continuously rotated by the motor and is pinned to the upper end of a vertical shaft 3G held in alignment by a radial bearing 32 with the end of the motor shaft iii. K

The power driver l 8 is formed at its lower portion with a conical clutching surface S4 for engaging a correspondingly shaped internal clutching surface 36 on a driven clutch member 38. The clutch member 38 extends upwardly from a sleeve d0 freely slidable and rotatable on the shaft 30 and provided with an integrally formed helical gear 42 at its central portion for driving a sewing cam shaft and a pattern cam shaft of the machine. The driven clutch member 33 is held in engagement with the clutching surface of the power driver by a heavy compression spring 44 between the sleeve 40 and a bearing carried by the power drive frame. The outside surface of, the driven clutch member is also conical in shape and is adapted to engage an annular braking member i6 attached to the frame of the machine.

Means are provided for disengaging the driven clutch member from the main driver at the proper time and wedging it within the braking member 46 to arrest the movement of the helical gear 42 and the sewing cam shaft and pattern cam shaft driven thereby. These means are substantially the same as in the driving and stopping mechanisrn described in the U. S. patent to Topham No. 1,791,176 granted February 3, 1931, and comprise a suitably shaped cam slot i8 formed in the sleeve 4B for engagement with-a spring pressed lock bolt 50. The lock bolt is mounted in a carrier 52 rigidly secured to a horizontal rock shaft 54 mounted in the frame of the power drive. The lock bolt 50 is mounted to slide in an arm of the carrier and is urged toward the cam slot 48 by a spring 56 (see Fig. 6).

While the machine is in operation and while the sewing and pattern cam shafts are being driven, the lock bolt 50 is out of engagement with the cam slot 48, and the clutch member 3B is held in engagement with the power driver t8 by the force exerted by the spring 46 on the sleeve 46. To disengagef the driven clutch member from the power driver, the lock bolt is allowed to engage the cam slot '-iil in the sleeve 43 and, at a certain point in the revolution of the sleeve, the carrier for the bolt is held against movement, thereby causing the lock bolt and cam groove to cooperate in forcing the sleeve fill with the clutch member 36 away from the power driver against the force of the spring 44, and bringing the brake surface on the driven clutch member into engagement with the xed braking member 56. While the clutch members are in engagement, the horizontal arm of the carrier in which the bolt is mounted is maintained in raised position by a spring 5l stretched between the vertical arm of the carrier and the frame of the machine. When the lock bolt is allowed to move toward the cam slot, it engages the outer surface of the sleeve 46 and .slides into the slot when the slot registers with the bolt. Continued rotation of the clutch member causes the lock bolt to be moved downwardly and the lock bolt carrier to be moved in a clockwise direction. Movement of the lock bolt carrier in a counter-clockwise direction, and movement of the lock bolt in an upward direction is then prevented by the engagement of the vertical arm of the lock bolt carrier by a spring pressed latch 58 (Fig. 14.) The lock bolt carrier with the lock bolt 56 is then held against movement and the continued rotation of the sleeve l0 causes the separation of the clutch members by the cooperative action of the cam slot i8 and the stationarily held lock bolt 56.

Outsole shoe sewing machines of the character herein described are heavily constructedand of considerable mass, requiring a heavy braking force to be applied in stopping at a definite point. This force is at a maximum with the parts in a stopped position and produces a large amount of friotional resistance ,to the releasing movement of the latch 58 from engagement with the bolt carrier. To relieve the operator from the exertion n-ecessary to overcome this resistance, starting mechanism is provided in accordance with a feature of the present invention to supply an unlimited amount of power for application in releasing the latch. This mechanism comprises a helical gear 62 (see Figs. 4 and 5) on the power driver I8 engaging a gear fifi formed on a sleeve 66 rotating freely on a horizontal crank shaft 68 (Fig. 15) journaled in the power starting casing, from which shaft through connections, hereinafter described, the latch 53 is actuated to release the lock bolt carrier and the lock bolt is withm drawn from the cam slot 48. Beside the gear il@ on the sleeve 66 there is a spur gear 'I0 meshed with a gear 'I2 rotatable on a horizontal countershaft 14, also having bearings in the casting l2. The gear 'I2 is formed with a conical opening at one side and a correspondingly shaped hub member 'I6 fixed to the counter-shaft I4 enters into frictional engagement with the inner surface of gear l2. At the opposite side of the gear, a thrust bearing 'I8 reacts against a compression spring 86, to prevent slippage between the hub member and the gear 12. The outer end of spring 86 is backed by an adjustable collar 82 threaded onto the shaft lll. At the end of the counter-shaft opposite from the gear '12, is xed a spur gear B meshing with a gear 86 mounted loosely on the crank shaft 68 and comprising the driving part of an auxiliary Horton or other one-revolution clutch. The driven part 88 of the clutch is keyed. to a collar 90 xed on the crank shaft 68. The

gear 86 is continuously rotated by the train of gears, thus described, including the helical gear 62 on the main driver, gears 64 and l on the crank shaft 66, gear I2 rotating with the countershaft l, and gear 64 meshing with gear 86.

The one-revolution clutch is` held in uncoupled condition bya slidable abutment 62 (see Figs. 4 and 7) carried on a rod 9d extending from a bell crank pivoted to the power starting casting I2 by a screw 96. The abutment 92 is yieldingly maintained in position by a spring IE6 for absorbing the shock which results from the stopping action of a projection |62 from the control disk I63 of the clutch. Pivotal-ly mounted on the bell crank 95 is a pawl member Hill engaging with ratchet teeth H16, on the driven part 88 of the clutch. This pawl aids in maintaining the clutch in released condition by preventing reverse rotation of the` driven parts. The pawl is resiliently maintained in contact with the ratchet teeth by a spring m8 tensed between the forward end of the pawl and the bell crank.

To enable the crank shaft to be operated, the constantly rotating gear 86 is coupled with the driven part 83 of the one-revolution clutch by rocking the bell crank 9S about its pivot screw 96, thereby moving the slidable abutment 92 out of contact with the projection 62 on the control disk of the clutch and connecting the driving gear 86 with the crank shaft 68 through 'one complete revolution. The bell crank 9S is rocked by means of a manually operated handle, HS pivoted at H2 on the power starting frame, the lower end being thrust outwardly by a compression spring H4 acting between the upper end of the handle and the frame. To prevent more than one revolution of the crank shaft for a single actuation of the manually operated handle iii). a latch H6 is pivotally mounted on the handle and extends into contact with a projec- -L tion I I8 on the lower arm of the bell crank 66. A spring 26 extends between the handle Hf! and the latch H6 to force it downwardly and hold it in a substantially horizontal position with a shoulder on the latch in engagement with the side of the handle. Manual operation of the handle 'Ill thrusts the latch H6 endwise against the projection H8 to rock the bell crank and release the projection on the clutch from the abutment 92. To prevent the crank shaft' 68 from making more than one revolution, the driven part 68 of the clutch carries a cam |22 and. upon rotation of the crank shaft, the cam engages a roller E24 attached to the end of a release trigger 26 fulcrumed loosely at its central part on the i counter-shaft M. As the roller I24 is thrust downwardly by the cam I 22, the other end `Il of the trigger rises to strike the latch IIi its free end and lifts it from engagement with the projection H8 on the bell crank. As soon as the projection IIB is cleared by the latch H6, the. abutment 92 falls into the path of the projection |62 under the action of a spring 32 compressed between the horizontal arm of the bell crank and the casting frame. As the crank shaft continues to rotate, the projection |62 strikes abutment S2 and the auxiliary clutch is again uncoupled.

Rotation of the crank shaft actuates the lock bolt 56 and the carrier latch 58 to free the main driven clutch member 38 from engagement with the` stationary brake and allow it to rise under the pressure of the compression spring, into driving relation with the power driver I8. For this purpose, the crank shaft 68 is provided with a crank |34 which actuates a` vertical pitman |36 connected at its lower end with a vertical slide |38 (see Figs. 6 and 7). At an intermediate part of the pitman there are provided an opening and a lug carrying a vertically adjustable stop screw |40. The latch 58 is released from the lock bolt carrier and the lock bolt 50 is withdrawn from engagement with the cam slot 4B by the action of the stop screw |46 through connections which are substantially the same as disclosed in Patent No. 1,791,176 and which comprise a pair of fingers |42 rotatable with a shaft |44 (see Fig. 14) journaled in the frame of the'machine. These fingers thrust against a collar |43 at the end of the clutch bolt to withdraw it. The shaft |44 is rotated by an arm i46 fixed to one end of the shaft and connected at its outer end to a link |48. The lower end of the link is pivotally connected by screw |50 to a horizontal lever |52 pivoted at |54 to the frame of the machine, the extending end of which lever is fashioned with av handle portion to provide for manual actuation, and is connected by an upwardly extending spring |56 for maintaining it in raised position so that the fingers |42 will not normally engage the collar at the end of the clutch bolt 50. The link |48 also carries a camp block |58 adjustable longitudinally of the link. This camp block is adjusted to release the latch 58 from the bolt carrier by striking a pair of ngers extending from the latch, which project at either side of the link |48. The screw |50 is formed with an elongated head portion to enter the slot in the pitman |36 and as the pitman descends during rotation of the crank shaft, stop screw strikes the head of screw |50 (see Fig. 7), causing a release of the latch 58 from the bolt carrier and a withdrawal of the bolt from engagement with the cam slot 43 in the driven clutch member 38. As soon as the driven clutch member is released, it' moves upwardly under the action of the compression spring 44 into driving relation with the main driver I8 to set the machine in operation` The ngers |42 are retained in clutch releasing position by a pivoted latch |60 acting against a projection |62 on one of the fingers. A spring is stretched between the latch and the frame of the machine to hold the latch |60 in engagement with the projection on the nger.

Manual operation of the handle ||ll causes a single rotation of the crank shaft 68 and a reciprocation of the pitman |36 to move link |48 downwardly to release the main driven clutch member and start the machine. If the parts become so tightly wedged that breakage is imminent, gear 'i2 runs idly on the countershaft 74, exerting only the turning force provided by the frictional engagement with the conical hub member 16.

The sewing mechanism and the jack actuating mechanisms are driven by the driven clutch member 38 through two separate transmission systems as in the machine disclosed in the patent to Morrill No. 1,834,471, dated December 1, 1931. In the present construction, however, a helical gear |68 which meshes with the gear 42 formed on the sleeve 4B of the driving clutch member is mounted to rotate freely on the main horizontal sewing cam shaft |66 and is detachably connected to the shaft by means of a clutch member |10 mounted to rotate with and slide longitudinally on the shaft and provided with clutch projections engaging cooperating projections on the face of the gear |68. The clutch member |10 may be moved out of engagement with the gear |66 by means of a clutch shifting member |12 fulcrumed to swing about the pivot |54 on which the lever |52 is mounted, and connected by a short horizontal link |14 with an eccentric pin on the pivot of a hand lever |75.

The stitch-forming devices (see Figs. 1, 5. and 6) include the curved hook needle, indicated at |19, the awl at H66, the work support at 46|, the presser-foot at E62, the shuttle at |83, and the looper at |84. The work feeding devices of the machine are constructed and arranged to impart a continuous feeding movement to the Work, and to this end the werk support and presser-foot are mounted upon a laterally sliding carriage or feed slide $85, and the needle and awl are also mounted upon this carriage but, at certain times during the stitch-forming and work-feeding cycle, are moved in the line of feed independently of the carriage.

The jack actuating mechanisms are driven from the gear 42 on the driven clutch member through a vertical shaft |86 (see Figs. 5 and 7) carrying a helical gear |67 at its upper end, meshingr with the gear 42 and terminating in a slotted enlargement |88 at its lower end. Below the end of the enlargement, a serrated clutch block 589 is arranged with a key slidable in a slot axially of the shaft.. Springs maintain the block in a lowered position against the upper toothed surface of an enlarged upper end of a short vertical shaft |96 (see Fig. 1G). Surrounding the shaft |90 is a sleeve |95 which is driven from the shaft i90 through a variable speed mechanism and which has attached at its lower end a pinion |92, this driving mechanism as sc far described being the same as in the mav chine of Patent No. 1,834,471. From the pinion |92 the pattern cam shaft for controlling the position of the jack is driven through a train. of gears comprising a gear |94 meshing with the pini-on G92, an overrunning clutch |96 contained within the gear, a sleeve |93 on which the gear is supported and to which one member of the clutch is keyed, a gear 200 keyed at the lower end of the sleeve, a gear 202 meshing with the gear 200 and secured to the lower end of a short vertical shaft 204, an elongated pinion 206 fast on the shaft 204, a gear 208 meshing with the pinion 266 and a series of similar gears 2|@ secured together and to the gear 203, arranged to mesh with a gear 2|2 at the upper end of the pattern cam shaft. The pattern cam shaft is thus driven continuously so long as the driven ciutch member 38 engages the main driver i5, the speed of rotation depending on the adjustment of thc variable speed mechanism between the shaft |90 and the surrounding sleeve li. This variable speed mechanism, as in the machine of Patent No. 1,834,471, comprises a ratchet wheel 2|4 fast upon the shaft |90, a series of pawl carriers 2|6 pivotally mounted on the upper end of sleeve |9|, a pawl 2|8 mounted on each pawl carrier and spring pressed into engagement with the ratchet 2|4 and an adjustable cam plate 220 (see Fig. 2) provided with a cam groove, engaging pins 222 projecting upwardly from the pawl carriers.

'Ihe mechanism for automatically initiating the nal stopping movements of the machine is actuated from the pattern cam shaft, indicated at 224, after it has made nearly a complete revolution. This mechanism acts to release the lock bolt 50 and permits it to move into engagement with the cam slot 48 of the main clutch member 38 and is substantially the same as the mechanism disclosed in Patents No. 1,791,176 and No. 1,834,471. This mechanism (see Figs. 2, 5, 6, and 7) comprises the gear 2|2 at the upper end of the pattern cam shaft and a block 226 secured to the upper surface of the gear, which block, after the pattern cam shaft has made nearly a complete revolution, engages and swings backwardy a pawl lever 228, and through the pawl moves a lever 230 pivotally mounted at 232 on the machine frame. A sliding rod 234 pivotally connected at its rear end to the lever 230 and at its forward end is arranged to engage the end of a dog 236 pivotally mounted at the left hand end of a lever 236. The arrangement of these parts is such that as the pattern cam shaft nears the end of a revolution the lever 260 is rocked, the rod 234 is moved longitudinally 'towards the front of the machine and the level' 238 is swung forwardly at its left hand end about its pivot. The right hand end of the lever 238 is connected by means of a slotted link 242 to the left hand end of another short centrally fulcrumed lever 244. The right hand end of the short lever is provided with a V-shaped recess inwhicli the lower wedge shaped end of a vertical sliding control bar 246 rests (see Figs. 6 and 7); When the left hand end of lever 238 is moved forwardly, the right hand end containing the V-shaped recess of the short lever 244 is actuated to raise the vertically sliding control bar 246. As fully illustrated and described in 'Patent No. 1,791,176, connections to the control bar include a step-by-step timing device and a snap switch 248 having an actuating arm or lever 250 adapted to be actuated by an off-center spring 252 in one direction or the other according to the position of the clutch controlling mechanism. The switch is operated during the first movement of the control bar and electrical connections are made to the motor I4 to reduce its speed during the next three cycles of operation of the stitch-forming devices. The control bar is given a step-by-step upward movement in time with the rotation of the sewing cam shaft until the upper end of the bar strikes the latch |66, releasing the ngers |42 holding the lock bolt 50 out of engagement with the cam slot 4S on the main driven clutch' member. At the same time, the latch 56 is allowed to rise by upward movement of the clamp block |58 on the link |46 connected with the retracting lingers |42. The entry of the lock bolt 50 within the cam slot 48 causes the driven clutch member to become disengaged from the main driver and wedged within the braking member 46 to arrest the movement of the main sewing cam shaft. The control car 246 upon releasing the latch |60 is itself released from the step-by-step mechanism and returned to its lowest position in engagement with the V-shaped end of the short lever 244 which, during the nal movements of the machine, has been restored to its neutral position. control bar 246 may also be raised to stop the machine by a manually operable lever 264 (see Fig. 7) pivoted on the frame of the machine.

rlhe jack and its supporting structure are substantially the same as in the machine of Patent No. 1,834,471, more fully described in U. S. Patent to Laurence E. Topham and Alfred R. Morrill No. 1,616,714, dated February 8, 1927, and in applicants co-pending application above referred to. The jack comprises a toe supporting arm 256 (see Fig. l) rigid with the hollow spindle 250 and a heel supporting arm 260 pivoted at its lower end upon the upper end of the spindle. The jack support comprises a horizontal arm 262 (see Figs. 2, 3, 8, and 9) in the forward end of which the lower end of the jack spindle is rotatably mounted by means of a gi-mbal joint. The arm 262 is mounted by means of pivotal connections 264 to swing vertically upon a support 266, and the support 266 is pivotally mounted upon substantially vertical hollow bearing surfaces 268 and 210 carried by a frame 212 which is pivotally mounted on the main base 2 of the machine by horizontal bearings 214.

During the sewing operation, tipping and rotating movements are imparted to the shoe to maintain the shoe at all times in proper positl n, tipping movements being imparted by movthe lower end of the jack spindle forwardly and rearwardly of the machine, and laterally, and stating movements being imparted by rotating the jack about the axis of the spindle. With the exception of the arrangement of the cable through which the jack spindle is related, the mechanisms for producing these movements are substantially the same as in the machines of the patents above referred to. For moving the lower end of the jack forwardly and rearwardly, a cam lever 216 is provided, one arm of which pivotally connected to the frame 212 by means connected by means of a link 282 to one arm of a lever 284, the other arm of which is engaged by a cam on the pattern cam shaft. To rotate the jack spindle, a helically grooved drum 236 is provided, having a downwardly extending pivot pin 268 journaled in the outer end of the horizontal arm 262 and the jack spindle is connected to the drum 286 through the gimbal joint above referred to. The drum is rotated by a cord or cable 290 wound substantially one and a half times -around the drum and lying in the groove of the drum and secured against slippage by a clamp 292. From the drum one end of the cable passes over a pulley 294 on the base or" the machine to a pulley 296 on a weight 298, and thence over a series of pulleys, as in the machine of Patent No. 1,834,471 to a control lever 366 hereinafter described.

In the other direction, the cable passes rearwardly from the drum within enclosing anges formed on the arm 262 and around a horizontally arranged sheave 302 on the arm, the iner circumferential portion of which sheave, according to a feature of the invention, lies substantially tangent to the axis of the pivotal connections 264. The cable, after passing from the horizontal sheave, is guided by an approximately vertically arranged sheave 394 rotatable on the sup-port 266 and arranged with a portion of its inner circumference also tangential to the axis of the pivotal connections 264. The cable eX- tending from the sheave 304 passes'through the centers of bearings 268 and 210 and under a third sheave 306 mounted on bearings in the frame 212. The sheaves 304 and 306 are positioned so that the portion of the cable extending between them passes substantially through the axis of rotation of the vertical bearings. The

Acable passes fromv the sheave 366 and around a fourth .sheavc 308 also carried by the Frame 212 and having a portion .of i-ts inner circumference approximately Vtangent .to the axis of the horizontal bearings y.214 Xed on the main frame of the machine. The cable, after passing from the sheave 308 is secured to a wheel 313 level with the horizontal bearings 214 and attached at `the bottom end of a shaft 3I2 having its upper and lower .ends mounted on bearings 3|4 and 316, respectively, upon the frame of the machine. The wheel 310 is so arranged .that the cable will extend tangentially from it to sheave 368. The upper end of the yshaft .312 is provided with a ,pinion which meshes with a segmental rack 313 on the outer end of a lever 320, the other end of which Ylever is engaged by a cam on the pattern cam shaft (see Fig. 3). By thus arranging the sheaves 3.6.2, 364, 366, and 368, and .so that portions of the spindle rotating cable 266 pass in substantial alignment or coincident with .the respective axes `of the lpivot bearings of the members of the jack supporting .structure .relativemovements of .the .different members in no vWay affect the length of cable between Athe grooved wheel and the actuated end of the cable. For this reason, other jack positioning movements .do not interfere with .the rotation .of .the jack. The use of the helically grooved drum at the lower end of the jack rotating spindle also insures free and easy rotation-of the jack about the axis of .the spindle without .irregular movements frcm interference between -overlapping turns of cable.

Mechanism similar to that illustrated and decrbed in Patents No. 1,616,714 and No. 1,834,471 is provided in the illustrated machine for adjusting the speed of the pattern cam shaft in ,accordance with the size of the shoeto `be operated on. To .this end the kcam plate 226 (see Fig. 2) for controlling the movement -of the pawl carriers 216 of the variable speed `mechanism is pivotally mounted upon Vthe frame of the machine and provided 'at its free-end witha toothed segment Yportion meshing with a correspondingly toothed segment 322 also .pivotally mounted upon 'the' frame of the machine. The segment 322 is actuated by an arm'324 movable with the segment and attached at its outer end to one end of a controller bar 326 acting when moved endwise 'in either direction to shift the cam plate 226. Movement is imparted to the controller bar by engagement of a pin 328 on a forward `extension of a lever 336 with one .of two inclined surfaces formed on the end ofthe bar`326 remote from .the arm 324. The lever 330 is adjusted in accordance with the position given to the shoe inmoving the jack into operating position with relation to the 'stitch-forming devices preliminary to starting the machine, as fully explained in the patents above referred to. In starting the machine, the controller barl 326 is moved bodily into 'engagement with the pin 328 through the action of a link 332 pivotally connected at one end to the controller bar and at the other to a Vlever 334 fulcrumed on the frame of the machine. As 'the lever 334 is rotated about its fulcrum point and the controller bar is moved into contact withthe pin 328, the lever 334 is Vlatched in position by engagement of a projection on the lever with a latch 336.

'In the illustrated machine, the lever 334 for changing the r.speed adjustment of the pattern cam shaft is operated from connections to the power starting mechanism in starting the ma- .chine in operation. For this purpose, the slide 138 (see Figs. 6 and 7) connected with the crank shaft 68 on the power starting mechanism ls formed at its lower end with rack teeth 338 engaging a'pinion 346 rotating on a stud shaft fixed to the frame of the machine. The pinion 340 is attached to rotate with a gear .342 meshing with a second rack 344 on the end of a rod 346 slidable horizontally across the front of the machine base. left hand side of the machine by a spring 348 (see Fig. 2) fastened at one end to the rod and at the other to the frame. Adjacent an eXtension of lever 334 there is provided an upwardly extending pin 356 which engages the lever when the rod 346 is moved towards the right. Operation of the slide ISB from the power starting mechanism causes rotation of the gear 342 and movement of the rod 346 to the right, rocking the lever 334 to latched position and providing the proper adjustment for the speed of the pattern cam shaft in accordance with the size of a shoe.

As in the machines of Patents Nos. 1,834,471 and 1,616,714, the shoe is fed in the present machine by the devices of the sewing mechanism acting directly on the shoe. In order to maintain the shoe in time with the position changing movements imparted to the shoe from a pattern cam shaft, an improved mechanism has been provided for coordinating the movements imparted to the jack bythe pattern cam shaft with the feeding movements imparted by the sewing mechanism. This limproved mechanism comprises the control lever 3D0 mounted at 35i on the base of the machine vframe `to swing in a horizontal plane and connected at its forward end through a lost motion device and a link 352 to the toe supporting arm 256 of the jack. For moving the vcontrol lever 366, 'the central part is connected by means of links '354 and 356 tothe end of an .arm y356 which is operable with a .cam lever 360 engaging a cam on the pattern cam shaft. The links 354 and 356 are-pivotally connected together and to the free end of a vswinging guiding link 362. The link 362 is fulcrumed upon a lever 364 z which vis held locked in position during the operation of a shoe. To adapt the machine for operation on shoes of different sizes, the lever 364 is pivotally mounted at its forward end upon the machine base so that it can be adjusted to change the position of the fulcrum of the swinging guiding link 362. The fulcrum carrying lever 364 is held locked in .adjusted position during the operation on the shoe by mechanism comprising a rod 366 pivotally connected to the rear end of 1 the fulcrum carrying lever 364 and arranged to slide in a block pivotally mounted on the machine base. The rod 366 is engaged by the inner cam shaped ends of short levers 358 mounted in the block and the outer ends of these levers are connected by a pin and slot connection with a cross bar 310. This cross bar is pivotally mounted on the rear end of a rod 312, the forward end of which is pivotally connected to the central part of the controller bar 326. Rotation of the lever 334 during operation ofthe power starting mechanism in starting the machine moves the controller bar 326 and the rod 312 forwardly of the machine to lock the rodV -1366 in fixed position. The placing of `a new shoe on the jack in operating position in the'machi-ne acts to release the lever 334, as explained in Patent No. 1,616,714, above referred to, so that the fulcrum carrying lever 364 is unlocked and adjustment of the mechanism for actuating the control vlever can The rod is normally tensed toward the again be made by the movement of a newly jacked shoe to starting position in the machine.

The lost motion device between the control lever 339 and the link 352 comprises a small lever 314, the hub of which extends on either side of a lug 313 on the control lever through which lug a pivot pin 318 isiitted (see Figs. 11, 12, and 13). The lever` 314 extends slightly to one side and forwardly from its pivot and is pivotally connected to the link 352 leading to the toe of the jack. On the opposite side of its pivot, an extending arm of the lever 31d is arranged to oscillate between two adjustable set screws 389 and 382 threaded into lugs carried by the forward end of the control lever. An insulating member 334 is mounted on a horizontal pivot 333 in a recess formed in the lever 314, and carries an electric switch contact 388 for wiping two stationary contacts 39E! and 392 mounted in insulating material at the end of the control lever 309. rllhe contact 392 is made shorter than the contact 390 so that in one position with the lever 314 against the set screw 330 no conductive connection exists between the contacts but, when the lever 314 is thrust against the set screw 392, a circuit will be completed. Opening or closing of the circuit containing contacts 390 and 392 acts to vary the rotary speed of the pattern cam shaft through the gear train connecting it to the main driven clutch member, as will be described.

The train of gears, above described, for driving the pattern cam shaft from the main driven clutch member is proportioned to cause the forward end of the lever 336 to move at a slightly slower rate than the toe portion of the jack as it is moved under the feeding action of the stitchforming devices on the shoe. The difference in movement of these two parts reacts on the small lever 314, rotating it about its pivot pin to close an electric circuit connected between the contacts 393 and 392. This circuit, illustrated diagrammatically in Figure 1l, comprises a flexible cable 393 carried bythe control lever 333 and provided with wires connected to the contacts 339 and 392. Closing the circuit between contacts 396 and 392 energizes an electromagnet 394, the armature of which acts to produce a change in the gearing through which the pattern cam. shaft is driven. This gearing comprises a gear 393 loosely mounted to turn freely on a shaft 393 keyed to the sleeve i90 and on which shaft the low speed driving pinion |92 is fixed (see Fig. lil). Longitudinal displacement of gear 393 is prevented by set screws 45(1,threaded into the gear 396 and arranged with their inner ends extending into an annular groove 402 in the surface of the shaft 398. The gear 395 meshes with a gear 334 rotating with the sleeve E98 and the ratio of teeth between these gears is such that when the gear 334 is driven by the gear 396, a greater movement of sleeve E93 is produced than by a corresponding rotation of pinion 92 and the gear mit. The gear 434 is provided with a ring 436 having an inner conical frictional surproduced by the pinion I 92 and the gear 396 do not interfere on account of the overrunning action of the clutch 93 which permits the sleeve H98 to rotate faster when driven by the gear 404. The gear 396 is adapted to be rotated by a clutch member 4i2 sliding on the shaft 398 which is rotated from the short vertical shaft 86 driven from the main clutch. The member 412 is fixed to rotate with the shaft by a pin 4M extending diametrically through the member and through longitudinal slots in the shaft. The upper surface of the sliding member and the lower surface of the gear 393 areserrated with inter-engaging projections to establish a driving relation. The sliding clutch member M2 is moved into and out of engagement with the gear 399 by the movement of the armature of the magnet 394 through connections which comprise a split cylindrical block 4&6 fitting within a longitudinal hole in the shaft 339. The pin 414 passes through this block and thus connects the block with the clutch member. The magnet 394 is mounted directly below the shaft 398 on a bracket 453 and the armature of the magnet carries a short vertical rod 42E) extending upwardly from the armature core of the magnet. The block 4|6 is provided with a recess surrounding the head of a pin 422 threaded at its lower end in a block 424 clamped on the upper end of the vertical rod 429. A spring 426 surrounds the pin 422 and is interposed between the block 424 and the lower end of the cylindrical block M6. The construction and arrangement of these parts are such that a movement of the armature of the magnet 394 when the magnet is energized forces the clutch member 4t2 yieldingly into engagement with the gear 396, and a movement of the armature in the opposite direction when he magnet is de-energized, moves the clutch member out of engagement with the gear.

The circuit of` the magnet 394 is energized to increase the speed of rotation of the pattern cam shaft from a source of power 428 (see Fig. 1l) through relay contacts 439 and through connections to the coils surrounding the armature of the magnet. Contacts 43D are connected to energize the magnet 39l by a relay coil 432 connected to one terminal of a low volt-age transformer 434 and to the contact 399 mounted on the control lever 339. The contact 392 is connected to the other terminal of the transformer. High voltage connections between the transformer and the source of power 328 serve to furnish current to actuate the relay. The transformer 434 and the relay 432 are mounted in a box 436 attached to the side of the machine base, connecting wires being carried in ,flexible metal conduits. Connection between the contacts 390 and 392 is interrupted as soon as the control lever 393 has caught up with the feeding movements of the stitch forming devices and the change speed gear is shifted back again to low speed by deenergizing the magnet 394. This shifting continues throughout the stitching operation in accordance with the variations in movement between the shoe supporting jack and the control lever, the relative periods of low and high speeds providing sufficient range of speed variation.

The illustrated machine is also provided with mechanism which may be thrown into operation by the operator after the sewing mechanism and pattern cam mechanism are stopped to turn the pattern cam shaft backwardly. This mechanism is the same as that disclosed in Patent No. 1,616,714, and is thrown into operation by rocking alever S38 (see Fig. 7) ina direction to depress a clutch block lite (see Fig. i4). ln the present machine, however, the lever 38 is rocked manually instead of automatically as in the patented machine. The means for thus rocking lever 438 consist of a manually operable bell crank lever 442 pivoted at M4 on the machine frame and having one arm formed as a handle and the other arm forked to engage the outer end of the lever 438.' The clutch block 44B, being rotated continuously, is forced against a serrated block 468 connected with a gear 34S (see Fig. 10) meshing with pinion teeth 450 on the upper end of sleeve |98. The rotation imparted by block 44E) is in the proper direction to rotate the pattern cam shaft 22!! reversely whenever bell-crank lever 442 is actuated.

The nature and scope of the present invention having been indicated, and a machine embodying the several features having been specifically described, what is claimed iszl. A starting apparatus for power operated machines having, in combination, a continuously rotating driving member, a main driven shaft, a main clutch having driving and driven parts for rotatably connecting said driving member and driven shaft, a braking surface rotating with the shaft, a stationary cooperating braking surface, mechanism actuated by the shaft for separating the clutch parts and forcing the braking surfaces into engagement, an auxiliary shaft, an auxiliary clutch for rotatably connecting said driving member 4and auxiliary shaft, a manually actuable member for rendering the auxiliary clutch o-perative, connections actuated by the auxiliary shaft for releasing said main clutch parts and braking surfaces to permit the separation of the braking surfaces and the engagement of the main clutch parts, and means acting automatically thereafter to render the auxiliary clutch inoperative.

2. A starting apparatus for power operated machines having, in combination, a continuously rotating driving member, a main driven shaft, a main clutch having driving and driven parts for rotatably connecting said driving member and driven shaft, a braking surface rotating with the shaft, a stationary cooperating braking surface, means actuated by the shaft for separating the clutch parts and forcing the braking surfaces into engagement including a vibrating member and means driven by the shaft and cooperating with said member when held from vibration to move said 'brake members into engagement, a latch for holding the said vibrating member against movement, an auxiliary shaft, an auxiliary clutch for rotatably connecting said driving member .and auxiliary shaft, a manually actuable member for controlling the auxiliary clutch, and connections actuated by the auxiliary shaft for actuating the latch to release the vibrating member.

3. A starting apparatus for power operated machines having, in combination, a continuously rotating driving member, a main driven shaft, a main clutch having driving and driven parts for rotatably connecting said driving member and driven shaft, a braking surface rotating with the shaft, a stationary cooperating braking surface, a cam rotating with the shaft, a lever arranged to be vibrated by the cam and cooperating with the cam when held from vibration to separate the clutch partsr and force the braking surfaces into engagement, a latch for holding the lever from vibration, an auxiliary shaft, an auxiliary clutch for rotatably connecting said driving member and auxiliary shaft, a manually actuable member for controlling the auxiliary clutch, and connections actuated by the auxiliary shaft for actuating the latch to release the lever.

fl. A starting apparatus for power operated machines having, in combination, a continuously rotating driving member, a main driven shaft, a main clutch having driving and driven parts for rotatably connecting said driving member and driven shaft, a braking surface rotating with the shaft, a stationary cooperating braking surface, a cam rotating with the shaft, a lever arranged to be vibrated by the cam and cooperating with the cam when held from vibration to separate the clutch parts and force the braking surfaces into engagement, a cam follower mounted on the lever to move into and out of engagement with the cam, a latch for holding the lever from vibration, an auxiliary shaft, an auxiliary clutch for rotatably connecting said driving member and auxiliary shaft, a` manually actuable member for controlling the auxiliary clutch, and connections actuated by the auxiliary shaft for actuating the latch to release the lever and for retracting the cam follower from engagement with the cam.

5. A starting apparatus for power operated machines having, in combination, a continuously rotating driving member, a main driven shaft, a main clutch having driving and driven parts for rotatably connecting said driving member and driven shaft, a stationary brake arranged adjacent the driven part of the main clutch, a spring for maintaining the clutch parts in engaging relation, means operated by the driven shaft while rotating under momentum for thrusting the driven clutch part away from the driving part and into progressively increasing frictional engagement with the brake member, and a releasing mechanism for said thrusting means comprising an auxiliary clutch driven by said driving member and a manually actuable member for rendering the auxiliary clutch operative, and means acting automatically to render the auxiliary clutch inoperative after said thrusting means has been released.

6. A starting apparatus for power operated machines having, in combination, a continuously rotating driving member, a main driven shaft, a

clutch having driving and driven parts acting under the inuence of a spring for rotatably connecting said driving member and said driven shaft, a locking bolt acting in its advanced position to maintain the clutch parts separated against the action of said spring, means for rel taining the locking bolt after being withdrawn, and means for withdrawing said locking bolt comprising said continuously rotating driving member, an auxiliary driving clutch, a manually actuable member for rendering said auxiliary clutch operative, and means acting automatically to render the auxiliary clutch inoperative after the locking bolt has been withdrawn.

7. A shoe machine having, in combination, a continuously rotating driving shaft, a main driven shaft, a clutch for rotatably connecting said driving shaft and driven shaft, a controlling mechanism for said clutch, means for operating upon a shoe, a shoe supporting jack movable to transfer the point of operation along the shoe, a

pattern cam shaft, connections adjustable according to the size of a shoe between the jack and the pattern cam shaft for controlling the position of the jack with relation to the operating means, devices for locking said connections in adjusted position, auxiliary power operated mechanism for actuating the clutch controlling mechanism for rendering the clutch operative to connect the driving and driven shafts and for actuating said locking devices to lock said connections in adjusted position, and a manually operable member for controlling said auxiliary mechanism.

8. A shoe machine having,` in combination, means for operating upon a shoe, a shoe supporting jack movable to transfer the point of operation along the shoe, means for controlling the position of the jack with relation to the operating means, a main driver for the machine, a clutch for connecting and disconnecting said operating and jack controlling means with said main driver, apparatus driven through the clutch for disconnecting the operating and jack controlling means subsequently to a predetermined movement of the jack with relation to the operating means, auxiliary mechanism driven by said main driver for actuating the clutch to connect the operating and jack controlling means with the driver, and a manually actuable member for controlling the operation of the auxiliary mechanism.

9. A shoe machine having, in combination, means for operating upon a shoe having a main operating shaft, a shoe supporting jack movable to transfer the point of operation along the shoe, a pattern cam shaft for controlling the position of the jack with relation to the operating means, a main driver for the machine, means including an auxiliary mechanism driven by said main driver for connecting said operating and pattern cam shafts to said main driver, a manually actuable member for controlling said auxiliary mechanism and a manually shiftable element for disconnecting one of said shafts from said driver While the other shaft remains connected in driving relation.

10.In a shoe machine, the combination of means for operating upon a shoe, a main operating shaft therefor, a shoe supporting jack, a pattern cam shaft for controlling the position of the jack with relation to the operating means, a main driver for the machine, means including an auxiliary mechanism driven by said main driver for connecting said operating and pattern cam shafts to said main driver, a manually actuable member for controlling said auxiliary mechanism, and a manually shiftable element for disconnecting said operating shaft from said driver while said pattern cam shaft remains connected.

11. In a shoe machine, the combination of means for operating upon a shoe having a main operating shaft, a shoe supporting jack, a pattern cam shaft for controlling the position of the jack with relation to the operating means, a main driver for the machine, means including an auxiliary mechanism driven by said main driver for connecting said operating and pattern cam shafts to said main driver, a manually actuable member for controlling said mechanism, a manually actuable member for disconnecting said operating shaft from said driver, a reverse drive gear for the pattern cam shaft, and an additional manually actuable member for` coupling said reverse drive gear to the pattern cam Shaft.

12. A shoe machine having, in combination, means for operating upon and feeding a shoe, a shoe supporting jack, a pattern cam shaft and Vconnections for changing the relative positions of the jack and the operating means to present the shoe properly to the operating means as the point of operation is transferred about the shoe, a driving shaft connected to said pattern cam shaft through an overrunning clutch, disconnectible supplementalgearing between saiddriving shaft and pattern cam shaft for changing the speed of rotation of said pattern cam shaft, and means for coupling and uncoupling said shafts through said supplemental gearing to maintain the proper time relation between the movements imparted to the shoe by the shoe feeding means and the pattern cam shaft.

13. A shoe machine having, in combination means for operating upon and feeding a shoe,

a shoe supporting jack, a pattern cam shaft and connections for changing the relative positions of the jack and the operating means to present the shoe properly to the operating means as the point of operation is transferred about the shoe, a driving shaft connected to said pattern cam shaft through an overrunning clutch, disconnectible supplemental gearing between said driving shaft and pattern cam shaft for changing the speed of rotation of said pattern cam shaft, a shock absorbing device arranged in said gearing, clutch members having inter-engaging serrations for coupling said shafts through said gearing, and means for actuating said clutch members to maintain the proper time relation between the movements imparted to the shoe by the shoe feeding means and the pattern cam shaft.

14. A shoe machine having, in combination, means for operating upon and feeding a shoe, a pattern cam shaft and connections for changing the relative positions of the jack and the operating means as the point of operation is transferred about the shoe, a driving shaft connected to said pattern cam shaft, disconnectible supplemental gearing between said driving shaft and pattern controlling shaft for changing the speed of rotation of said pattern controlling shaft, an arm under the control of said pattern controlling shaft movable with said jack, connections between said movable arm and jack, an electric switch having movable elements interposed between said connections, an electromagnet arranged in a circuit controlled by said switch, and

a connection between said gearing and electromagnet actuable to change the speed of rotation of said pattern cam shaft upon operation of said switch by coupling said driving shaft and pattern cam shaft through said supplemental gearing.

15. A shoe machine having, in combination, means for operating upon a shoe, a main operating shaft for said operating means, a movable shoe supporting jack, means for feeding the shoe, mechanism for changing the relative positions of the shoe and the operating means to present the shoe properly to the operating means as the point of operation is transferred about the shoe, a second rotatable shaft arranged in driving relation to said main operating shaft for driving said position changing mechanism, a main driver common to both said shafts, a clutch for coupling said shafts to the driver, a variable speed driving mechanism for adjusting the relative speeds of said shafts, concurrently with the coupling action of said clutch, a changeable selective gear means for varying ,the relative speeds of said shafts While rotating, and means for momentarily shifting the selective gear means upon variation of the relative speeds of operation upon the shoe of 

